The present application is related to x-ray sources.
An x-ray source can include an x-ray tube electrically coupled to a high voltage power supply. The power supply can provide a large bias voltage for the x-ray tube. The large voltage, between a cathode and an anode of the x-ray tube, and sometimes a heated filament, can cause electrons to emit from the cathode to the anode. The anode can include a target material. The target material can generate x-rays in response to impinging electrons from the cathode.
The following definitions, including plurals of the same, apply throughout this patent application.
As used herein, the phrase “dispersed evenly” means dispersed exactly evenly; dispersed evenly within normal manufacturing tolerances; or dispersed almost exactly evenly, such that any deviation from dispersed exactly evenly would have negligible effect for ordinary use of the device.
As used herein, the terms “on”, “located on”, “located at”, and “located over” mean located directly on or located over with some other material between. The terms “located directly on”, “adjoin”, “adjoins”, and “adjoining” mean direct and immediate contact.
As used herein, the term “monolithic” means seamless and continuous. A monolithic structure herein has the same material composition throughout. For example, a concrete wall, formed at a single time in a single pouring step, followed by a single curing step, is monolithic. As another example, a housing, formed at a single time in a single injection-molding step, is monolithic.
As used herein, the term “integrally-joined” and “integral” mean that the integrally-joined devices are formed together at the same time and are continuous without seams or joints between them.
As used herein, the term “parallel” means exactly parallel; parallel within normal manufacturing tolerances; or almost exactly parallel, such that any deviation from exactly parallel would have negligible effect for ordinary use of the device.
As used herein, the term “perpendicular” means exactly perpendicular; perpendicular within normal manufacturing tolerances; or almost exactly perpendicular, such that any deviation from exactly perpendicular would have negligible effect for ordinary use of the device.
As used herein, the term “same material composition” means exactly the same, the same within normal manufacturing tolerances, or nearly the same, such that any deviation from exactly the same would have negligible effect for ordinary use of the device.
As used herein, the term “x-ray tube” is not limited to tubular/cylindrical shaped devices. The term “tube” is used because this is the standard term used for x-ray emitting devices.
As used herein, the term “Al” means aluminum, “Ca” means calcium, “Cu” means copper, “Fe” means iron, “Mg” means magnesium, “Mn” means manganese, “Ni” means nickel, “Si” means silicon, “Sr” means strontium, and “Zn” means zinc.
As used here, the term “adjacent” refers to the proximity of two structures or elements. Particularly, elements that are identified as being “adjacent” may be either abutting or connected. Such elements may also be near or close to each other without necessarily contacting each other. The exact degree of proximity may in some cases depend on the specific context.
An x-ray source 40 can include an x-ray tube 32 and a power supply 31 enclosed within a housing. Desirable characteristics of the housing include (a) light weight (for easier transport), (b) high electrical conductivity (to protect the user from electrical shock), (c) high thermal conductivity (to remove heat generated during use), (d) corrosion resistance, (e) high strength, and (t) high electromagnetic interference shielding (to shield power supply components from external noise, to shield other electronic components from power supply noise, or both).
The invention includes a monolithic housing for an x-ray source 40. The monolithic housing can be part of an enclosure for the x-ray source 40. The monolithic housing can wrap at least partially around the power supply 31 and the x-ray tube 32. The invention also includes methods of making a monolithic housing for an x-ray source 40. The monolithic housings described herein, and housings made by these methods, can satisfy the needs of the prior paragraph. Each example housing or method may satisfy one, some, or all of these needs.
A monolithic housing 10 for an x-ray source is illustrated in
The monolithic housing 10 can include a power supply casing 11 and an x-ray tube casing 12. The power supply casing 11 and the x-ray tube casing 12 can be integrally-joined together. Integrally joining the power supply casing 11 and the x-ray tube casing 12 can provide a material structure that is consistent, resulting in uniform properties throughout. Integrally joining the power supply casing 11 and the x-ray tube casing 12 can minimize gaps and seams. Such gaps or seams could otherwise result in undesirable electrical charge flow paths along an edge, or contact resistance across the gap or seam. Without such gaps and seams, heat flow can be uniform and less interrupted.
The power supply casing 11 can have a cavity for insertion of a power supply 31. The x-ray tube casing 12 can have a hollow for insertion of an x-ray tube 32. The cavity of the power supply casing 11 can adjoin the hollow of the x-ray tube casing 12 to allow insertion of an x-ray source with an x-ray tube 32 and a power supply 31. The x-ray tube 32 can be rigidly-mounted to the power supply 31.
An x-ray source 30, with a power supply 31 electrically coupled to an x-ray tube 32, is illustrated in
An x-ray source 40, with a power supply 31 inside of the power supply casing 11 and an x-ray tube 32 inside of the x-ray tube casing 12, is illustrated in
The x-ray tube 32 can be fully enclosed by the x-ray tube casing 12 and the power supply 31, except for a small opening to allow emission of x-rays from the x-ray tube 32, and can resist electrical shock. For example, ≥90%, ≥95%, or ≥98% of the x-ray tube 32 can be enclosed by the x-ray tube casing 12 and the power supply 31.
The power supply casing 11 can wrap at least partially around the power supply 31. The power supply casing 11 can include three sidewalls 11w and a base 11b, and thus enclose the power supply 31 on four of six sides to resist electrical shock.
There can be interior rib(s) 13 on an inner-face of sidewalls 11w of the power supply casing 11 (see
The x-ray tube casing 12 can wrap at least partially around the x-ray tube 32. The x-ray tube casing 12 can encircle the x-ray tube 32. The x-ray tube casing 12 can encircle the x-ray tube 32 along a length of the x-ray tube from a cathode to an x-ray window of the x-ray tube 32. The x-ray tube casing 12 can encircle the x-ray tube 32 along a major portion of a length of the x-ray tube 32, such as for example along ≥50%, ≥75%, or ≥90% of the length. Even if the x-ray tube casing 12 does not encircle the x-ray tube 32 along a majority of its length, it can be helpful for the x-ray tube casing 12 to encircle electrical connections between the power supply 31 and the x-ray tube 32. Thus, electrical shock can be resisted.
The monolithic housing 10 can be a single, integral unit formed by injection molding, as described below. Pellets having the following composition can be fed by a heated screw into the mold.
The monolithic housing 10 can include one or some of the following chemical elements. The material of the monolithic housing 10 can be selected to facilitate electrical shielding, electrical conductivity, and/or heat dissipation. Total weight percent of all chemical elements is 100%.
The monolithic housing 10 can include Mg. For example, a minimum weight percent Mg can be ≥50%, ≥75%, or ≥85%. Example maximum weight percent Mg can include ≤85%, ≤95%, or ≤99%. Mg can be dispersed evenly throughout the monolithic housing 10.
The monolithic housing 10 can include Al. For example, a minimum weight percent Al can be ≥2%, ≥4%, or ≥8%. Example maximum weight percent Al include ≤8%, ≤14%, or ≤20%. Al can be dispersed evenly throughout the monolithic housing 10.
The monolithic housing 10 can include Zn. For example, a minimum weight percent Zn can be ≥0.1%, ≥0.3%, or ≥0.7%. Example maximum weight percent Zn include ≤0.8%, ≤1.2%, or ≤3%. Zn can be dispersed evenly throughout the monolithic housing 10.
The monolithic housing 10 can include Al, Mg, Mn, and Zn. The monolithic housing 10 can include Al, Cu, Fe, Mg, Mn, Ni, Si, and Zn. The monolithic housing 10 can include Al, Ca, Cu, Fe, Mg, Mn, Ni, Si, Sr, and Zn. These chemical elements can be dispersed evenly throughout the monolithic housing 10 to achieve optimum performance.
A monolithic housing 50 is illustrated in
The x-ray tube casing 12 of monolithic housing 50 has a narrowing profile. The x-ray tube casing 12 can be wider closer to the power supply casing 11, and narrow moving away from the power supply casing 11. This narrowing can be linear. The x-ray tube casing 12 can have a conical frustum shape. These shapes can allow easier integration of the x-ray source 40 and the monolithic housing 10 into other tools. In addition, these shapes can allow easier assembly of the x-ray source 40 with the monolithic housing 10.
Monolithic housings 60 and 70 are illustrated in
As illustrated in
A base-wall inner angle 61 is an angle between the base 11b and the sides 11s, measured inside of the power supply casing 11 (
An end-side inner angle 71 is an angle between the end-wall 11e and each of the two sides 11s, measured inside of the power supply casing 11 (
As illustrated in
Monolithic housings 80 and 90 are illustrated in
Monolithic housings 80 and 90 include an array of ribs 81 on an exterior of the power supply casing 11 and an array of ribs 82 encircling the x-ray tube casing 12. One or both arrays of ribs 81 and 82 can be part of a monolithic housing 80 or 90, and thus integral with the rest of the monolithic housing 80 or 90. These arrays of ribs 81 and 82 can stiffen the x-ray tube casing 12, thus increasing its durability. These arrays of ribs 81 and 82 can remove heat from the housings 80 and 90. Contact resistance between separate devices can be avoided by forming the arrays of ribs 81 and 82 as part of the monolithic housing 80 or 90.
Both arrays of ribs 81 and 82 may be used. Only one array of ribs 81 or 82 may be used.
The array of ribs 81 on the power supply casing 11 can be adjacent to a transformer in the power supply 31. Thus, the array of ribs 81 can target heat removal at a location of heat generation.
As illustrated in
A first method of making a housing 141 for an x-ray source, or making an x-ray source 40, can include some or all of the following steps. These steps can be performed in the following order or other order if so specified. Some of the steps can be performed simultaneously unless explicitly noted otherwise in the claims. The housing 141 and the x-ray source 40 can have the properties of any monolithic housing described above.
Step 100 can include inserting an upper-mold 105 into a hollow-region 101 of a lower-mold 103, forming a power supply casing cavity 111 between the upper-mold 105 and the lower-mold 103. See
Step 120 can include inserting a slider-pin 107 from the upper-mold 105 into a hole 102 at a sidewall of the hollow-region 101, forming an x-ray tube casing cavity 122 between the slider-pin 107 and walls of the hole 102. The upper-mold 105 can include a channel 106 (
Step 130 can include injecting (e.g. through port 104 to port 254 in
Step 140 can include allowing the material 133 for the housing to solidify into a housing 141 for an x-ray source 40. The housing 141 can include a power supply casing 1I formed in the power supply casing cavity 111 and an x-ray tube casing 12 formed in the x-ray tube casing cavity 122. The power supply casing 11 and the x-ray tube casing 12 can be integral and monolithic. Step 140 can follow step 130. See
Step 150 can include removing the slider-pin 107 from the hole 102 of the lower-mold 103. The upper-mold 105 can include a channel 106 to allow the slider-pin 107 to move out of the upper-mold 105. Step 150 can follow step 140. See
Step 160 can include removing the upper-mold 105 from the hollow-region 101 (
Step 170 can include removing the housing 141 from the lower-mold 103. Step 170 can follow step 160. The lower-mold 103 can include three sections 251, 252, and 253, or at least three sections for easier removal of the housing 141. Step 170 can include pressing on ejection post(s) 72 to eject the housing 141 from the lower-mold 103. The ejection post(s) 72 are described above. See
Step 240 can include inserting an x-ray tube 32 into the x-ray tube casing 12 and a power supply 31 into the power supply casing 11, thus forming an enclosed x-ray source 40. Step 240 can follow step 170. See
Additional sheet(s) of material can be attached (e.g. bolted, glued, snapped into place, etc.) onto portion(s) of the power supply not covered by the power supply casing 11. The sheet(s) of material can be metallic.
A second method of making a housing 141 for an x-ray source, or making an x-ray source 40, can include some or all of the following steps. These steps can be performed in the following order or other order if so specified. Some of the steps can be performed simultaneously unless explicitly noted otherwise in the claims. The housing 141 and the x-ray source 40 can have the properties of any monolithic housing described above.
Step 180 can include (a) inserting an upper-mold 105 into a hollow-region 101 of a lower-mold 103, forming a power supply casing cavity 111 between the upper-mold 105 and the lower-mold 103, and (b) inserting a pin 187 into a hole 102 at a sidewall of the hollow-region 101, forming an x-ray tube casing cavity 122 between the pin 187 and walls of the hole 102. The pin 187 can be integral and monolithic with the upper-mold 105. Upper-mold 105 insertion into the hollow-region 101 can be simultaneous with pin 187 insertion into the hole 102. The upper-mold 105 and the pin 187 can be inserted at an angle as shown. See
Step 200 can include injecting (e.g. through port 104 to port 254 in
Step 210 can include allowing the material 133 for the housing to solidify into a housing 141 for an x-ray source 40. The housing 141 can include a power supply casing 11 formed in the power supply casing cavity 111 and an x-ray tube casing 12 formed in the x-ray tube casing cavity 122. The power supply casing 11 and the x-ray tube casing 12 can be integral and monolithic. Step 210 can follow step 200. See
Step 220 can include removing the upper-mold 105 from the hollow-region 101 of the lower-mold 103 and removing the pin 187 from the hole 102 of the lower-mold 103. Upper-mold 105 removal from the hollow-region 101 can be simultaneous with pin 187 removal from the hole 102. The upper-mold 105 and the pin 187 can be removed at an angle as shown. Step 220 can follow step 210. See
Step 230 can include removing the housing 141 from the lower-mold 103. The housing 141 can be removed at an angle as shown. Step 230 can follow step 220. The lower-mold 103 can include three sections 251, 252, and 253, or at least three sections for easier removal of the housing 141. Step 170 can include pressing on ejection post(s) 72 to eject the housing 141 from the lower-mold 103. The ejection post(s) 72 are described above. See
Step 240 can include inserting an x-ray tube 32 into the x-ray tube casing 12 and a power supply 31 into the power supply casing 11, thus forming an enclosed x-ray source 40. Step 240 can follow step 230. See
Additional sheet(s) of material can be attached (e.g. bolted, glued, snapped into place, etc.) onto portion(s) of the power supply not covered by the power supply casing 11. The sheet(s) of material can be metallic.
This application claims priority to U.S. Provisional Patent Application No. 63/195,300, filed on Jun. 1, 2021, which is incorporated herein by reference.
Number | Date | Country | |
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63195300 | Jun 2021 | US |